EP4303664A1 - Timepiece movement and timepiece comprising such a movement - Google Patents

Abstract

The present invention relates to a clock movement comprising an energy source, a gear train (11, 111) and a distribution mechanism (15, 115) linked kinematically to each other. The distribution mechanism (15, 115) is kinematically linked to at least one regulating member (12, 112). The distribution mechanism (15, 115) comprises a rest sub-assembly (16, 116) responsible for ensuring a function of blocking and releasing the energy source by the regulating body (12, 112) and a pulse sub-assembly (26, 126) responsible for maintaining the movement of the regulating member (12, 112), the rest sub-assembly (16, 116) being distinct from the sub-assembly d impulse (26, 126). The rest sub-assembly (16, 116) comprises an escape wheel called a rest escape wheel (17, 117), this rest escape wheel being fixed, and an anchor called a rest anchor (18, 118, 218). The impulse sub-assembly (26, 126) comprises an escape wheel called impulse escape wheel (27, 127) and an anchor called impulse anchor (28, 128, 228).The present invention also relates to a timepiece comprising such a clockwork movement.

Description

TECHNICAL AREA

The present invention relates to the field of mechanical watchmaking. More specifically, this invention relates to a watch movement comprising an energy source, a gear train and a distribution mechanism kinematically linked together, said distribution mechanism being kinematically linked to at least one regulating member, this distribution mechanism comprising a rest sub-assembly responsible for ensuring a function of blocking and releasing the energy source by the regulating member and a pulse sub-assembly responsible for maintaining the movement of the regulating member regulation, this rest subset being distinct from the impulse subset.

The present invention also relates to a timepiece comprising such a clockwork movement.

PRIOR ART

Conventional mechanical watches generally include an energy source, a counting member, a distribution member, a regulating member and a display. The regulating organ is often formed of a sprung balance. The distribution member often includes an escape wheel and an anchor actuating the hairspring of the hairspring balance.

Many current watch movements use a so-called Swiss anchor which provides two distinct functions. On the one hand, it ensures the blocking of the escape wheel during part of the movement cycle of the balance wheel. On the other hand, it provides the pendulum with the impulses which allow it to maintain its movement.

During the impulse phase, that is to say the phase during which the anchor provides energy to the balance, a relatively large quantity of energy must be supplied to the anchor so that the latter can in turn transmit energy to the pendulum. The lower the energy transmitted to the balance, the lower the amplitude of the movement of the balance. The isochronism of the watch movement may be affected.

In conventional movements using a Swiss lever escapement, part of the available energy is used to make the escape wheel make a recoil movement just before the impulse phase. This energy is therefore not available to maintain the movement of the pendulum and therefore represents a loss of energy.

In these conventional movements, the anchor pivots around a fixed axis and the escape wheel pivots around another fixed axis. In certain movements, the escape wheel is fixed relative to a plate or to the case of the timepiece and the anchor pivots around an axis which moves relative to the fixed escape wheel.

In this case, it is not the escape wheel which performs a slight recoil movement before the impulse phase, but the axis of the anchor and therefore the anchor as a whole. In all cases, energy is used for a recoil movement, this energy being lost to the pendulum.

This problem of energy loss is more particularly important on escapements in which the escape wheel is fixed, such as for example the Potter escapement.

It is therefore important to find a solution to make the best use of the available energy, that is to say to transmit maximum energy to the sprung balance while minimizing losses.

Another problem can occur with existing movements due to the slight recoil of the escape wheel or the pallet pin. To increase the amplitude of the movement of the balance, it is in principle possible to increase the energy supplied by the energy source, for example the barrel. However, if too large a quantity energy is supplied to the escape wheel, the balance wheel may not have enough energy to make this escape wheel or the lever axis carry out the recoil movement making it possible to release the anchor of the escape wheel tooth. The escape wheel must therefore receive a sufficiently large quantity of energy so that it can transmit it to the lever, then to the sprung balance, but not so large that the escapement is blocked. For some moves, especially moves containing a Potter-like escape, this balance can be difficult to find.

Another problem concerns the distribution of energy to the balance wheel over time. As is well known when the energy source of the watch movement is a barrel, in conventional movements, the energy distributed to the balance wheel generally decreases over time. This energy can be too strong at the beginning, when the mainspring is fully tensioned, and then become too weak later, when the mainspring is relaxed.

The regularity of the movement of the balance contributes to the precision of the movement. The variation of the energy distributed over time therefore reduces the isochronism of the movement.

It is therefore advantageous to produce an escapement mechanism of the "constant force" type, i.e. a movement in which the energy distributed to the balance remains substantially stable over time, whatever the state of charge of the source. 'energy.

There are timepiece movements in which the blocking and pulsing functions are separated in order to optimize the use of energy. Such a movement is in particular described in the patent application published under No. WO 2020/007619 . This movement, however, has several flaws. On the one hand, it does not solve the problem of variation in energy distribution over time. In fact, this mechanism is not a constant force escapement. On the other hand, it cannot be adapted to a movement comprising a fixed escapement wheel, of the “Potter escapement” type. In addition, this document describes a trigger escapement with lost strokes. As a result, an impulse is not given to the balance at each alternation, which is not optimal. Furthermore, due to the presence of cams on a guide path made in the side of a wheel, this mechanism is extremely complex to produce.

DESCRIPTION OF THE INVENTION

The present invention proposes to overcome the disadvantages of the mechanisms of the prior art by producing a clock movement in which the components are optimized to operate efficiently, so as to reduce, as far as possible, the losses linked to a non-optimal use of available energy.

In addition, the energy which can be transmitted to the escape wheel can be large enough to ensure optimal movement of the balance wheel, while avoiding the risk of blocking the escape wheel or the anchor against the escape wheel. 'exhaust.

The energy transmitted to the balance remains stable over time and does not vary significantly depending on the state of the energy source.

This movement is also adapted to an escapement comprising a fixed wheel, in particular of the “Potter escapement” type.

To achieve these goals, the blocking or resting functions of the anchor are separated from the impulsion function. This makes it possible to optimize the parts and their shapes so that they are as efficient as possible and so that the available energy is distributed and used as best as possible.

The aims of the invention are achieved by a clockwork movement as defined in the preamble and characterized in that the rest sub-assembly comprises an escape wheel called a rest escape wheel and an anchor called a rest anchor. , in that the rest escape wheel is fixed and in that the impulse subassembly comprises an escape wheel called impulse escape wheel and an anchor called impulse anchor.

The aims of the invention are also achieved by a timepiece comprising such a clockwork movement.

The watch movement of the invention separates the different functions of the distribution mechanism, namely the function of blocking and releasing part of the movement on the one hand and the function of driving the movement of the balance wheel in particular 'somewhere else. This is interesting in the sense that the different elements of this mechanism can be designed and produced in such a way as to optimize their operation and ensure that maximum energy available in the movement is transmitted to the components concerned and in particular to the balance spring. -spiral. In this way, the isochronism of the movement is improved.

In conventional watch movements, the same components, notably the escapement and the anchor, are used to achieve the blocking and releasing function on the one hand and the movement maintenance function on the other hand. To achieve this goal, a compromise may need to be made at the component level. This implies that the whole, although satisfyingly fulfilling both functions, does not fulfill any of them optimally.

By separating the locking and releasing function on the one hand and the impulse function, the recoil movement of the impulse escape wheel can be avoided.

In this way, the components can each be made in such a way as to perform their respective functions optimally. Furthermore, it is possible to make the components of the watch movement in such a way that the quantity of energy supplied to the balance wheel is optimal for its operation, without however risking the movement blocking.

BRIEF DESCRIPTION OF THE DRAWINGS

• la figure 1 est une vue générale en perspective d'une partie du mouvement d'horlogerie de l'invention, selon un premier mode de réalisation ;
• la figure 2 est une vue en coupe de la partie du mouvement d'horlogerie illustré par la figure 1 ;
• la figure 3 est une vue de détail de certains composants du mouvement d'horlogerie de la figure 1 ;
• la figure 4 est une vue de dessus d'une partie du mouvement d'horlogerie de la figure 1, dans une première position ;
• la figure 5 est une vue du mouvement d'horlogerie illustré par la figure 4, dans une deuxième position ;
• la figure 6 est une vue du mouvement d'horlogerie illustré par la figure 4, dans une troisième position ;
• la figure 7 est une vue générale en perspective d'une partie du mouvement d'horlogerie de l'invention, selon un deuxième mode de réalisation ;
• la figure 8 est une vue en coupe de la partie du mouvement d'horlogerie illustré par la figure 7 ;
• la figure 9a représente l'une des ancres utilisées dans le mouvement d'horlogerie de la figure 7 ;
• la figure 9b représente une autre ancre utilisée dans le mouvement d'horlogerie de la figure 7 ;
• la figure 10 est une vue de dessus d'une partie du mouvement d'horlogerie de la figure 7, dans une première position ;
• la figure 11 est une vue du mouvement d'horlogerie illustré par la figure 10, dans une deuxième position ;
• la figure 12 est une vue du mouvement d'horlogerie illustré par la figure 7, dans une troisième position ;
• la figure 13a représente une variante de l'une des ancres utilisées dans un mouvement d'horlogerie selon la présente invention ;
• la figure 13b représente une autre ancre utilisée dans un mouvement d'horlogerie selon la présente invention, dans la variante de la figure 13a ; et
• la figure 14 est une vue du mouvement d'horlogerie selon la présente invention, utilisant les ancres des figures 13a et 13b.

The present invention and its advantages will be better understood with reference to the appended figures and the detailed description of a particular embodiment, in which:

• there figure 1 is a general perspective view of a part of the clock movement of the invention, according to a first embodiment;
• there figure 2 is a sectional view of the part of the clock movement illustrated by the figure 1 ;
• there Figure 3 is a detailed view of certain components of the watch movement of the figure 1 ;
• there figure 4 is a top view of part of the clock movement of the figure 1 , in a first position;
• there figure 5 is a view of the clock movement illustrated by the figure 4 , in a second position;
• there Figure 6 is a view of the clock movement illustrated by the figure 4 , in a third position;
• there Figure 7 is a general perspective view of a part of the clock movement of the invention, according to a second embodiment;
• there figure 8 is a sectional view of the part of the clock movement illustrated by the Figure 7 ;
• there figure 9a represents one of the anchors used in the clock movement of the Figure 7 ;
• there figure 9b represents another anchor used in the clock movement of the Figure 7 ;
• there Figure 10 is a top view of part of the clock movement of the Figure 7 , in a first position;
• there Figure 11 is a view of the clock movement illustrated by the Figure 10 , in a second position;
• there Figure 12 is a view of the clock movement illustrated by the Figure 7 , in a third position;
• there figure 13a represents a variant of one of the anchors used in a watch movement according to the present invention;
• there figure 13b represents another anchor used in a watch movement according to the present invention, in the variant of the figure 13a ; And
• there Figure 14 is a view of the clock movement according to the present invention, using the anchors of the figures 13a and 13b .

MODE OF CARRYING OUT THE INVENTION

THE figures 1 to 6 illustrate a first embodiment of a watch movement according to the invention. THE figures 7 to 12 illustrate a second embodiment and the figures 13 And 14 illustrate a variant of the second embodiment of the invention.

In the figures, the parts having the same functions in the three embodiments illustrated bear the same reference number, increased by 100 for the second embodiment and by 200 for the specific elements of the variant illustrated by the figures 13 And 14 .

With reference to figures 1 to 6 , illustrating a first embodiment of the invention, the watch movement 10 comprises, in a conventional manner, an energy source (not shown) linked kinematically to a cog 11 of which only a part is illustrated.

The watch movement of the invention further comprises a regulating member 12 comprising a balance-spring assembly formed of a conventional balance 13 and a balance-spring 14.

A non-conventional distribution mechanism 15 kinematically connects the cog 11 to the regulating member 12.

This distribution mechanism 15 comprises a first sub-assembly called rest sub-assembly 16. This rest sub-assembly 16 comprises a rest escape wheel 17 with internal teeth, of the Potter escapement type. It also includes an anchor, called rest anchor 18.

The rest anchor 18 has an axis of rotation 19 around which it pivots. It comprises two arms, namely an input arm 20a and an output arm 20b, each respectively maintaining an input pallet 21a and an output pallet 21b. The rest anchor 18 also includes a rod 22 ending in a fork 23 provided with an entry horn 23b and an exit horn 23a as well as a stinger 50.

The watch movement 10 according to the invention further comprises a plate 24 or double plate provided with a pin 25 cooperating with the fork 23 and the dart 50 of the rest anchor 18, in a manner known per se.

The distribution mechanism 15 comprises a second sub-assembly called impulse sub-assembly 26. This impulse sub-assembly 26 comprises an escape wheel called impulse escape wheel 27. It also includes an anchor, called impulse anchor 28 and an impulse spring 29. This impulse subassembly 26 further comprises a winding pinion 30 meshing with a fixed winding wheel 31. The winding pinion 30 is integral with one end of the impulse spiral 29 so that the rotation of the winding pinion 30 causes the recharge of the impulse spiral 29 with energy. The fixed winding wheel 31 is integral with a winding adjustment ring 32 arranged to adjust the pre-cocking of the impulse hairspring 29.

The impulse anchor 28 includes an input arm 33a and an output arm 33b respectively holding an input vane 34a and an output vane 34b.

In the first embodiment, the impulse anchor 28 pivots around an axis coincident with the axis of rotation 19 of the rest anchor 18. In this embodiment, the two anchors 18, 28 form a single piece and are not movable relative to each other. In other words, the two anchors can be considered as a single piece.

In this embodiment, the clockwork operates as described below.

First, let's assume the starting position is as follows. The impulse anchor 28 bears against a tooth 35 of the impulse escape wheel 27 so as to block it. The rest anchor 18 bears against a tooth 36 of the rest escapement wheel 17 so that these two components are stationary relative to each other. The impulse hairspring 29 is loaded and the balance 13 of the hairspring balance has reached the end of its travel and is heading back towards its point of balance. This position is illustrated by the Figure 4 .

When the balance 13 reaches and exceeds its point of equilibrium, the pin 25 of the plate 24 acts on the fork 23 of the rest anchor 18 and activates this rest anchor. The entry pallet 21b of the rest anchor which was resting against the tooth 36 of the rest escape wheel 17 moves to release the rest anchor 18 from this tooth. Simultaneously with the movement of the rest anchor 18, the impulse anchor 28 is pivoted, the impulse anchor and the rest anchor being integral and made in a single piece.

The release of the input pallet 21b from the rest anchor 18 relative to the tooth 36 of the rest escapement wheel 17 is concomitant with the release of the input pallet 34a from the impulse anchor 28 relative to the tooth 35 of the impulse escape wheel 27. The impulse spiral 29 being loaded, the release of the impulse escape wheel 27 allows the tooth 35 of the escape wheel to impulse 27 to act on the input pallet 34a of the impulse anchor 28.

By the shape of the teeth of this impulse escape wheel 27 and by the arrangement and shape of the pallets 34 of the impulse anchor, the energy transmitted by the impulse spiral 29 to the wheel d The pulse exhaust 27 is transferred to the pulse anchor 28.

The impulse anchor 28 and the rest anchor 18 forming a single piece, the energy transmitted from the impulse balance spring 29 to the impulse escape wheel 27 is directly transmitted to the fork 23 of the anchor rest 18, then to the sprung balance of the regulating body 12.

During these movements, the rest anchor 18 moved by half a tooth relative to the rest escape wheel 17. This has the effect of moving the winding pinion 30 relative to the fixed wheel winding 31. This rotation of the winding pinion 30 tightens the impulse hairspring 29 and therefore recharges it with energy. Thus, the energy released during these different movements and transmitted to the sprung balance so as to maintain its movement, is compensated or replaced by energy coming from the energy source, via the winding pinion 30.

In this way, the energy is transmitted from the energy source to the balance 13 passing through the rest anchor 18, this rest anchor 18 and the impulse anchor 28 being optimized to each fulfill their function.

In the second embodiment illustrated by the figures 7 to 12 , the watch movement 110 comprises, as in the first embodiment illustrated, an energy source (not shown) linked kinematically to a gear train 111.

The watch movement of the invention further comprises a regulating member 112 comprising a balance-spring assembly formed of a conventional balance 113 and a balance-spring 114.

A distribution mechanism 115 kinematically connects the gear train 111 to the regulating member 112.

This distribution mechanism 115 comprises a first rest sub-assembly 116. This rest sub-assembly 116 comprises a rest escape wheel 117 with internal teeth, of the Potter escapement type. It also includes a rest anchor 118.

The rest anchor 118 has an axis of rotation 119 around which it pivots. It comprises two arms, namely an entry arm 120a and an exit arm 120b respectively holding an entry pallet 121a and an exit pallet 121b. The rest anchor 118 also includes a rod 122 ending in a fork 123 provided with an entry horn 123b and an exit horn 123a as well as a stinger 150.

The timepiece movement 110 according to the invention further comprises a plate 124 or double plate provided with a pin 125 cooperating with the fork 123 of the rest anchor 118.

The distribution mechanism 115 comprises an impulse sub-assembly 126. This impulse sub-assembly 126 comprises an impulse escape wheel 127. It also comprises an impulse anchor 128 and an impulse hairspring 129 This impulse subassembly 126 further comprises a winding pinion 130 meshing with a fixed winding wheel 131. The winding pinion 130 is integral with one end of the impulse spiral 129 so that the rotation of the winding pinion 130 generates the recharge of the impulse hairspring 129 with energy. The fixed winding wheel 131 is also integral with an adjustment ring 132 arranged to adjust the pre-cocking of the impulse hairspring 129.

The impulse anchor 128 comprises an input arm 133a and an output arm 133b respectively holding input vane 134a and an output vane 134b. In this embodiment, the rest anchor 118 and the impulse anchor 128 are not made in one piece, as in the embodiment of the figures 1 to 6 .

The rest anchor 118 comprises a connecting rod 140 secured to the rod 122. This connecting rod 140 comprises a housing 141 whose function is explained below.

The impulse anchor 128 pivots on an axis of rotation 142. The impulse anchor 128 further comprises a connecting rod 143 secured, in the illustrated embodiment, to the input arm 133a. This connecting rod 143 comprises, at its end opposite the input arm 133a, a pivot 144 dimensioned and arranged so as to be able to be introduced into the housing 141 of the rest anchor 118.

The impulse anchor 128 and the rest anchor 118 are integral in the sense that the movement of one of the anchors causes the movement of the other anchor. They are not in one piece, but are formed of two distinct elements mounted one on the other in a pivoting manner via the pivot 144 and the housing 141.

In this embodiment, the clock movement 110 operates as follows. First, assume that the starting position is the same as that used as the starting position with reference to the first embodiment illustrated by the figures 1 to 6 .

As a reminder, in this position, the impulse anchor 128 rests against a tooth 135 of the impulse escape wheel 127 so as to block it. The rest anchor 118 rests against a tooth 136 of the rest escapement wheel 117. The impulse hairspring 129 is loaded and the balance 113 of the hairspring balance has reached the end of its travel and is starting again in the direction from its point of equilibrium. This position is illustrated by the Figure 10 .

When the balance 113 reaches and exceeds its point of balance, the pin 125 of the plate 124 acts on the fork 123 and activates the rest anchor 118. The output pallet 121b moves to release the rest anchor 118 from the tooth 136. The rest anchor 118 pivots on its axis 119. The connecting rod 140 carrying the housing 141 is also pivoted around the axis of rotation 119 of the rest anchor 118.

The movement of the rest anchor 118 causes the movement of the pivot 144 and consequently, the pivoting of the impulse anchor around its axis of rotation 142.

The axes of rotation 119, 142 of the two anchors being distinct, the shape of the housing 141 is designed to allow the pivot 144 to move practically without play in this housing.

This causes the entry pallet 134a to be released from this impulse anchor 128 from the tooth 135 of the impulse escape wheel 127. The impulse hairspring 129 being loaded, the release of the escape wheel impulse 127 has the effect that energy from the impulse hairspring 129 is transmitted to the impulse escape wheel 127.

By the shape of the teeth of this impulse escape wheel 127 and by the arrangement and shape of the pallets 134 of the impulse anchor 128, the energy transmitted by the impulse spiral 129 to the wheel pulse exhaust 127 is transferred to pulse anchor 128.

The energy received by the impulse anchor 128 by the impulse hairspring causes the rotation of the impulse anchor 128 around its axis of rotation 142, which causes the movement of the connecting rod 143 and the pivot 144 of this impulse anchor. These movements generate the movement of the housing 141 of the rest anchor and consequently, the pivoting of the rest anchor 118 around its axis of rotation 119. The energy of the impulse hairspring 129 is therefore transmitted to the rest anchor 118 which transfers it to the hairspring 114 of the hairspring balance via the fork 123.

During these movements, the rest anchor 118 moved by half a tooth relative to the rest escape wheel 117. This has the effect of moving the winding pinion 130 relative to the fixed wheel. winding 131. This rotation of the winding pinion 130 tightens the impulse hairspring 129 and recharges it with energy. Thus, the energy released during these different movements and transmitted to the sprung balance so as to maintain its movement, is compensated or replaced by energy coming from the energy source, via the winding pinion 130.

THE figures 13 And 14 illustrate a variant of the second embodiment illustrated by the figures 7 to 12 . In this variant, essentially the shape of the anchors is different.

In this embodiment, the movement comprises a rest anchor 218 and impulse anchor 228. Unlike the rest anchor 118 of the second illustrated embodiment, the rest anchor of this embodiment does not include fork. The rod 222 of this rest anchor 218 comprises a housing 241 arranged to receive a connecting pivot 244 secured to the impulse anchor 228. For the rest, this rest anchor is similar to the rest anchor 118 of the mode previous achievement.

The impulse anchor 228 of the embodiment illustrated by the figures 13 And 14 comprises a fork 223 provided with an input horn 223a and an output horn 223b as well as a stinger 250. For the rest, this impulse anchor is similar to the impulse anchor of the embodiment illustrated by the figures 7 to 12 .

In the previous embodiment, the pin 125 of the plate 124 acts on the horns of the fork of the rest anchor which is linked to the impulse anchor. In the embodiment illustrated by the figures 13 And 14 , the pin 225 of the plate (not shown) acts on the input horn 223a of the impulse anchor 228. This impulse anchor being linked to the rest anchor 218 via the connecting pivot 244 which is capable of moving in the housing 241 of the rest anchor, the movement of one of the anchors implies the movement of the other anchor.

Apart from the zone on which the pin 225 of the plate acts, the operation of the movement of the timepiece illustrated by the figures 13 And 14 is the same as that of the timepiece illustrated by the figures 7 to 12 .

Separating the functions of a conventional anchor into two separate anchors allows optimization of each function. In a movement including a Swiss lever escapement in particular, the lever must disengage from the escape wheel by imposing a slight recoil on the latter. This consumes energy which is no longer available for moving the balance and which is therefore lost. This also implies that if too much energy is supplied to the escape wheel, the balance wheel may not have enough of energy to make the escape wheel carry out the recoil movement allowing the anchor to be released from the tooth of the escape wheel. The escape wheel must therefore receive a sufficient quantity of energy so that it can transmit it to the lever, then to the sprung balance, but not so great that the escapement is blocked.

In the present invention, recoil movement is not required for the impulse escape wheel. The function of the pallets of the rest anchor is to ensure that this rest anchor is maintained against one of the teeth of the rest escape wheel, then to free itself from this tooth at the required moment. The recoil movement of the axis of the rest anchor can be moderate, as well as the force necessary for it. These pallets do not have the function of providing an impulse to the sprung balance. Their form can therefore be optimized for their unique function.

As for the impulse anchor, its function is to transmit energy to the balance spring. Its function is not to ensure stable blocking of the impulse escape wheel, this function being indirectly ensured by the rest anchor. The shape of the teeth of the impulse wheel and the shape, size and arrangement of the vanes can be optimized for this function. Furthermore, the energy provided by the impulse hairspring can be high due to the fact that it is not necessary to subject the impulse escape wheel to a retrograde movement when releasing a pallet of the impulse anchor. There is therefore no risk of blockage if the energy of the impulse hairspring is too great.

However, it is also possible to produce a rest anchor whose lifts make it possible to provide energy to the sprung balance, for example at the start of winding of the barrel.

Claims (10)

Clockwork movement comprising an energy source, a cog (11, 111) and a distribution mechanism (15, 115) linked kinematically to each other, said distribution mechanism (15, 115) being kinematically linked to at least one member regulation (12, 112), this distribution mechanism (15, 115) comprising a rest sub-assembly (16, 116) responsible for ensuring a function of blocking and releasing the energy source by the regulatory member (12, 112) and a pulse sub-assembly (26, 126) responsible for maintaining the movement of the regulating member (12, 112), this rest sub-assembly (16, 116 ) being distinct from the impulse sub-assembly (26, 126), this clockwork movement being characterized in that the rest sub-assembly (16, 116) comprises an escape wheel called the rest escape wheel (17, 117) and an anchor called a rest anchor (18, 118, 218), in that the rest escape wheel (17, 117) is fixed and in that the impulse sub-assembly (26 , 126) comprises an escape wheel called an impulse escape wheel (27, 127) and an anchor called an impulse anchor (28, 128, 228). Clock movement according to claim 1, characterized in that the impulse anchor (28, 128, 228) is kinematically linked to the rest anchor (18, 118, 218). Clockwork movement according to claim 1, characterized in that the impulse anchor (28, 128, 228) and the rest anchor (18, 118, 218) are integral with one another. Clockwork movement according to claim 1, characterized in that the rest anchor (18) and the impulse anchor (28) pivot around a common axis of rotation (19). Clock movement according to claim 1, characterized in that the rest anchor (18) and the impulse anchor (28) are in one piece. Clock movement according to claim 1, characterized in that the impulse anchor (128) comprises a connecting rod (143) of the impulse anchor, in that the rest anchor (118) comprises a connecting rod (140) of the rest anchor, in that one of the connecting rods (140, 143) comprises a housing (141) and the other of said connecting rods comprises a pivot (144) arranged to be able to pivot in said housing (141) and in that the impulse anchor (128) is kinematically linked to the rest anchor (118) via said rods connection (140, 143), housing (141) and pivot (144). Timepiece movement according to claim 1, characterized in that one of the anchors among the rest anchor (18, 118, 218) and the impulse anchor (28, 128, 228) comprises a fork (23 , 123, 223) arranged to cooperate with a pin (25, 125, 225) of a plate (24, 124) of the watch movement, the other anchor being devoid of a fork arranged to cooperate with said pin. Clock movement according to claim 1, characterized in that the impulse sub-assembly (26, 126) comprises an impulse spring (29, 129) and a winding pinion (30, 130), and in that one end of said impulse spiral (29, 129) is integral with the winding pinion (30, 130). Clock movement according to claim 8, characterized in that the impulse sub-assembly (26, 126) comprises a fixed winding wheel (31, 131) meshing with said winding pinion (30, 130). Timepiece comprising a movement as claimed in any one of claims 1 to 9.

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